------------- -- Methods -- ------------- local pi = math.pi local abs = math.abs local ceil = math.ceil local max = math.max local random = math.random local atan2 = math.atan2 local sin = math.sin local cos = math.cos local function diff(a, b) -- Get difference between 2 angles return atan2(sin(b - a), cos(b - a)) end local function clamp(val, _min, _max) if val < _min then val = _min elseif _max < val then val = _max end return val end local vec_add = vector.add local vec_normal = vector.normalize local vec_len = vector.length local vec_dist = vector.distance local vec_dir = vector.direction local vec_dot = vector.dot local vec_multi = vector.multiply local vec_sub = vector.subtract local yaw2dir = minetest.yaw_to_dir local dir2yaw = minetest.dir_to_yaw --[[local function debugpart(pos, time, tex) minetest.add_particle({ pos = pos, texture = tex or "creatura_particle_red.png", expirationtime = time or 0.1, glow = 16, size = 24 }) end]] --------------------- -- Local Utilities -- --------------------- local get_node_def = creatura.get_node_def --local get_node_height = creatura.get_node_height_from_def function creatura.get_collision(self, dir, range) local pos, yaw = self.object:get_pos(), self.object:get_yaw() if not pos then return end local width, height = self.width or 0.5, self.height or 1 dir = dir or yaw2dir(yaw) pos.x = pos.x + dir.x * width pos.z = pos.z + dir.z * width local cos_yaw = cos(yaw) local sin_yaw = sin(yaw) local width_i = width / ceil(width) local height_i = height / ceil(height) local pos_x, pos_y, pos_z = pos.x, pos.y, pos.z local dir_x, dir_y, dir_z = dir.x, dir.y, dir.z local pos2 = {x = pos_x, y = pos_y, z = pos_z} local collision pos.y = pos.y + height * 0.5 range = range or 4 local low_score for _ = 0, range do if collision then return collision end pos_x = pos_x + dir_x pos_y = pos_y + dir_y pos_z = pos_z + dir_z pos2.y = pos_y for x = -width, width, width_i do pos2.x = cos_yaw * ((pos_x + x) - pos_x) + pos_x pos2.z = sin_yaw * ((pos_x + x) - pos_x) + pos_z for y = height, 0, -height_i do if y < self.stepheight or 1.1 then break end pos2.y = pos_y + y if get_node_def(pos2).walkable then local score = abs(pos.y - pos2.y) * vec_dot(dir, vec_dir(pos, pos2)) if not low_score or score < low_score then low_score = score collision = pos2 end end end end end end creatura.get_collision_ranged = creatura.get_collision local get_collision = creatura.get_collision local function get_avoidance_dir(self) local pos = self.object:get_pos() if not pos then return end local _, col_pos = get_collision(self) if col_pos then local vel = self.object:get_velocity() vel.y = 0 local vel_len = vec_len(vel) * (1 + (self.step_delay or 0)) local ahead = vec_add(pos, vec_normal(vel)) local avoidance_force = vec_sub(ahead, col_pos) avoidance_force.y = 0 avoidance_force = vec_multi(vec_normal(avoidance_force), (vel_len > 1 and vel_len) or 1) return vec_dir(pos, vec_add(ahead, avoidance_force)) end end local function get_collision_single(pos, water) local pos2 = {x = pos.x, y = pos.y, z = pos.z} local n_def = get_node_def(pos2) if n_def.walkable or (water and (n_def.groups.liquid or 0) > 0) then pos2.y = pos.y + 1 n_def = get_node_def(pos2) local col_max = n_def.walkable or (water and (n_def.groups.liquid or 0) > 0) pos2.y = pos.y - 1 local col_min = col_max and (n_def.walkable or (water and (n_def.groups.liquid or 0) > 0)) if col_min then return pos else pos2.y = pos.y + 1 return pos2 end end end function creatura.get_avoidance_lift(self, pos2, range) range = ceil(max(range or 1, 0.5)) local height_half = (self.height or 1) * 0.5 local center_y = pos2.y + height_half local check_pos = {x = pos2.x, y = center_y, z = pos2.z} -- Find ceiling and floor collisions local def local ceil_pos local floor_pos for i = 1, range, 0.5 do -- 0.5 increment increases accuracy if ceil_pos and floor_pos then break end check_pos.y = center_y + i def = creatura.get_node_def(check_pos) if not ceil_pos and (def.walkable or minetest.get_item_group(def.name, "liquid") > 0) then ceil_pos = check_pos end check_pos.y = center_y - i def = creatura.get_node_def(check_pos) if not floor_pos and (def.walkable or minetest.get_item_group(def.name, "liquid") > 0) then floor_pos = check_pos end end -- Calculate direction to average point of collisions check_pos.y = center_y local offset = {x = 0, y = height_half + range, z = 0} if not ceil_pos then ceil_pos = vec_add(check_pos, offset) end if not floor_pos then floor_pos = vec_sub(check_pos, offset) end local dist_up = ceil_pos.y - center_y local dist_down = floor_pos.y - center_y local altitude = (dist_up + dist_down) / 2 return ((check_pos.y + altitude) - center_y) / range * 2 end function creatura.get_avoidance_lift_aquatic(self, pos2, range) range = ceil(max(range or 1, 0.5)) local height_half = (self.height or 1) * 0.5 local center_y = pos2.y + height_half local check_pos = {x = pos2.x, y = center_y, z = pos2.z} -- Find ceiling and floor collisions local ceil_pos local floor_pos for i = 1, range, 0.5 do -- 0.5 increment increases accuracy if ceil_pos and floor_pos then break end check_pos.y = center_y + i if not ceil_pos and minetest.get_item_group(creatura.get_node_def(check_pos).name, "liquid") < 1 then ceil_pos = check_pos end check_pos.y = center_y - i if not floor_pos and minetest.get_item_group(creatura.get_node_def(check_pos).name, "liquid") < 1 then floor_pos = check_pos end end -- Calculate direction to average point of collisions check_pos.y = center_y local offset = {x = 0, y = height_half + range, z = 0} if not ceil_pos then ceil_pos = vec_add(check_pos, offset) end if not floor_pos then floor_pos = vec_sub(check_pos, offset) end local dist_up = ceil_pos.y - center_y local dist_down = floor_pos.y - center_y local altitude = (dist_up + dist_down) / 2 return ((check_pos.y + altitude) - center_y) / range * 2 end ---------------------------- -- Context Based Steering -- ---------------------------- local steer_directions = { vec_normal({x = 1, y = 0, z = 0}), vec_normal({x = 1, y = 0, z = 1}), vec_normal({x = 0, y = 0, z = 1}), vec_normal({x = -1, y = 0, z = 0}), vec_normal({x = -1, y = 0, z = -1}), vec_normal({x = 0, y = 0, z = -1}), vec_normal({x = 1, y = 0, z = -1}), vec_normal({x = -1, y = 0, z = 1}) } -- Context Methods function creatura.get_context_default(self, goal, steer_dir, interest, danger, range) local pos = self.object:get_pos() if not pos then return end local width, height = self.width or 0.5, self.height or 1 local y_offset = math.min(self.stepheight or 1.1, height) pos.y = pos.y + y_offset local collision local ray = minetest.raycast(pos, vec_add(pos, vec_multi(steer_dir, width + range)), false, false) local pointed = ray:next() if pointed and pointed.type == "node" and creatura.get_node_def(pointed.under).walkable then collision = pointed.under end if collision then local dir2goal = vec_normal(vec_dir(pos, goal)) local dir2col = vec_normal(vec_dir(pos, collision)) local dist2col = vec_dist(pos, collision) - width local dot_score = vec_dot(dir2col, dir2goal) local dist_score = (range - dist2col) / range interest = interest - dot_score danger = dist_score end return interest, danger end function creatura.get_context_large(self, goal, steer_dir, interest, danger, range) local pos = self.object:get_pos() if not pos then return end local width, height = self.width or 0.5, self.height or 1 local y_offset = math.min(self.stepheight or height) pos.y = pos.y + y_offset local collision = creatura.get_collision(self, steer_dir, range) if collision then local dir2goal = vec_normal(vec_dir(pos, goal)) local dir2col = vec_normal(vec_dir(pos, collision)) local dist2col = vec_dist(pos, collision) - width local dot_score = vec_dot(dir2col, dir2goal) local dist_score = (range - dist2col) / range interest = interest - dot_score danger = dist_score end return interest, danger end function creatura.get_context_small(self, goal, steer_dir, interest, danger, range) local pos = self.object:get_pos() if not pos then return end pos = vector.round(pos) local width = self.width or 0.5 local collision = get_collision_single(vec_add(pos, steer_dir)) if collision then local dir2goal = vec_normal(vec_dir(pos, goal)) local dir2col = vec_normal(vec_dir(pos, collision)) local dist2col = vec_dist(pos, collision) - width local dot_score = vec_dot(dir2col, dir2goal) local dist_score = (range - dist2col) / range interest = interest - dot_score danger = dist_score end return interest, danger end function creatura.get_context_small_aquatic(self, goal, steer_dir, interest, danger, range) local pos = self.object:get_pos() if not pos then return end pos = vector.round(pos) local width = self.width or 0.5 local pos2 = vec_add(pos, steer_dir) local collision = minetest.get_item_group(get_node_def(pos2).name, "liquid") < 1 and pos2 if collision then local dir2goal = vec_normal(vec_dir(pos, goal)) local dir2col = vec_normal(vec_dir(pos, collision)) local dist2col = vec_dist(pos, collision) - width local dot_score = vec_dot(dir2col, dir2goal) local dist_score = (range - dist2col) / range interest = interest - dot_score danger = dist_score end return interest, danger end -- Calculate Steering function creatura.calc_steering(self, goal, get_context, range) if not goal then return end get_context = get_context or creatura.get_context_default local pos, yaw = self.object:get_pos(), self.object:get_yaw() if not pos or not yaw then return end range = math.max(range or 2, 2) local dir2goal = vec_normal(vec_dir(pos, goal)) local output_dir = {x = 0, y = dir2goal.y, z = 0} -- Cached variables local dir for _, _dir in ipairs(steer_directions) do dir = {x = _dir.x, y = dir2goal.y, z = _dir.z} local score = vec_dot(dir2goal, dir) local interest = clamp(score, 0, 1) local danger = 0 if interest > 0 then -- Direction is within 90 degrees of goal interest, danger = get_context(self, goal, dir, interest, danger, range) end score = interest - danger output_dir = vector.add(output_dir, vector.multiply(dir, score)) end return vec_normal(output_dir) end -- DEPRECATED function creatura.get_context_steering(self, goal, range, water) local context = creatura.get_context_default local width, height = self.width, self.height if width > 0.5 or height > 1 then context = creatura.get_context_large elseif water then context = creatura.get_context_small_aquatic end return creatura.calc_steering(self, goal, context, range) end ------------- -- Actions -- ------------- -- Actions are more specific behaviors used -- to compose a Utility. -- Move function creatura.action_move(self, pos2, timeout, method, speed_factor, anim) local timer = timeout or 4 local function func(_self) timer = timer - _self.dtime self:animate(anim or "walk") local safe = true if _self.max_fall and _self.max_fall > 0 then local pos = self.object:get_pos() if not pos then return end safe = _self:is_pos_safe(pos2) end if timer <= 0 or not safe or _self:move_to(pos2, method or "creatura:obstacle_avoidance", speed_factor or 0.5) then return true end end self:set_action(func) end creatura.action_walk = creatura.action_move -- Support for outdated versions -- Idle function creatura.action_idle(self, time, anim) local timer = time local function func(_self) _self:set_gravity(-9.8) _self:halt() _self:animate(anim or "stand") timer = timer - _self.dtime if timer <= 0 then return true end end self:set_action(func) end -- Rotate on Z axis in random direction until 90 degree angle is reached function creatura.action_fallover(self) local zrot = 0 local init = false local dir = 1 local rot = self.object:get_rotation() local function func(_self) if not init then _self:animate("stand") if random(2) < 2 then dir = -1 end init = true end rot = _self.object:get_rotation() local goal = (pi * 0.5) * dir local step = _self.dtime if step > 0.5 then step = 0.5 end zrot = zrot + (pi * dir) * step _self.object:set_rotation({x = rot.x, y = rot.y, z = zrot}) if (dir > 0 and zrot >= goal) or (dir < 0 and zrot <= goal) then return true end end self:set_action(func) end ---------------------- -- Movement Methods -- ---------------------- -- Pathfinding --[[local function trim_path(pos, path) if #path < 2 then return end local trim = false local closest for i = #path, 1, -1 do if not path[i] then break end if (closest and vec_dist(pos, path[i]) > vec_dist(pos, path[closest])) or trim then table.remove(path, i) trim = true else closest = i end end return path end]] creatura.register_movement_method("creatura:theta_pathfind", function(self) local path = {} local box = clamp(self.width, 0.5, 1.5) local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos then return end pos.y = pos.y + 0.5 -- Return true when goal is reached if vec_dist(pos, goal) < box * 1.33 then _self:halt() return true end self:set_gravity(-9.8) -- Get movement direction local steer_to = get_avoidance_dir(_self, goal) local goal_dir = vec_dir(pos, goal) if steer_to then goal_dir = steer_to if #path < 1 then path = creatura.find_theta_path(_self, pos, goal, _self.width, _self.height, 300) or {} end end if #path > 0 then goal_dir = vec_dir(pos, path[2] or path[1]) if vec_dist(pos, path[1]) < box then table.remove(path, 1) end end local yaw = _self.object:get_yaw() local goal_yaw = dir2yaw(goal_dir) local speed = abs(_self.speed or 2) * speed_factor or 0.5 local turn_rate = abs(_self.turn_rate or 5) -- Movement local yaw_diff = abs(diff(yaw, goal_yaw)) if yaw_diff < pi * 0.25 or steer_to then _self:set_forward_velocity(speed) else _self:set_forward_velocity(speed * 0.33) end if yaw_diff > 0.1 then _self:turn_to(goal_yaw, turn_rate) end end return func end) creatura.register_movement_method("creatura:pathfind", function(self) local path = {} local steer_to local steer_int = 0 self:set_gravity(-9.8) local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos or not goal then return end if vec_dist(pos, goal) < clamp(self.width, 0.5, 1) then _self:halt() return true end -- Calculate Movement local turn_rate = abs(_self.turn_rate or 5) local speed = abs(_self.speed or 2) * speed_factor or 0.5 steer_int = (not steer_to and steer_int > 0 and steer_int - _self.dtime) or 1 / math.max(speed, 1) steer_to = (steer_int <= 0 and creatura.calc_steering(_self, goal)) or steer_to if steer_to then path = creatura.find_lvm_path(_self, pos, goal, _self.width, _self.height, 400) or {} if #path > 0 then steer_to = vec_dir(pos, path[2] or path[1]) end end -- Apply Movement _self:turn_to(dir2yaw(steer_to or vec_dir(pos, goal)), turn_rate) _self:set_forward_velocity(speed) end return func end) -- Steering creatura.register_movement_method("creatura:steer_small", function(self) local steer_to local steer_int = 0 self:set_gravity(-9.8) local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos or not goal then return end if vec_dist(pos, goal) < clamp(self.width, 0.5, 1) then _self:halt() return true end -- Calculate Movement local turn_rate = abs(_self.turn_rate or 5) local speed = abs(_self.speed or 2) * speed_factor or 0.5 steer_int = (steer_int > 0 and steer_int - _self.dtime) or 1 / math.max(speed, 1) steer_to = (steer_int <= 0 and creatura.calc_steering(_self, goal)) or steer_to -- Apply Movement _self:turn_to(dir2yaw(steer_to or vec_dir(pos, goal)), turn_rate) _self:set_forward_velocity(speed) end return func end) creatura.register_movement_method("creatura:steer_large", function(self) local steer_to local steer_int = 0 self:set_gravity(-9.8) local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos or not goal then return end if vec_dist(pos, goal) < clamp(self.width, 0.5, 1) then _self:halt() return true end -- Calculate Movement local turn_rate = abs(_self.turn_rate or 5) local speed = abs(_self.speed or 2) * speed_factor or 0.5 steer_int = (steer_int > 0 and steer_int - _self.dtime) or 1 / math.max(speed, 1) steer_to = (steer_int <= 0 and creatura.calc_steering(_self, goal, creatura.get_context_large)) or steer_to -- Apply Movement _self:turn_to(dir2yaw(steer_to or vec_dir(pos, goal)), turn_rate) _self:set_forward_velocity(speed) end return func end) creatura.register_movement_method("creatura:walk_simple", function(self) self:set_gravity(-9.8) local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos or not goal then return end if vec_dist(pos, goal) < clamp(self.width, 0.5, 1) then _self:halt() return true end -- Calculate Movement local turn_rate = abs(_self.turn_rate or 5) local speed = abs(_self.speed or 2) * speed_factor or 0.5 -- Apply Movement _self:turn_to(dir2yaw(vec_dir(pos, goal)), turn_rate) _self:set_forward_velocity(speed) end return func end) -- Deprecated creatura.register_movement_method("creatura:context_based_steering", function(self) local steer_to local steer_int = 0 self:set_gravity(-9.8) local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos or not goal then return end if vec_dist(pos, goal) < clamp(self.width, 0.5, 1) then _self:halt() return true end -- Calculate Movement local turn_rate = abs(_self.turn_rate or 5) local speed = abs(_self.speed or 2) * speed_factor or 0.5 steer_int = (steer_int > 0 and steer_int - _self.dtime) or 1 / math.max(speed, 1) steer_to = (steer_int <= 0 and creatura.calc_steering(_self, goal, creatura.get_context_large)) or steer_to -- Apply Movement _self:turn_to(dir2yaw(steer_to or vec_dir(pos, goal)), turn_rate) _self:set_forward_velocity(speed) end return func end) creatura.register_movement_method("creatura:obstacle_avoidance", function(self) local box = clamp(self.width, 0.5, 1.5) local steer_to local steer_timer = 0.25 local function func(_self, goal, speed_factor) local pos = _self.object:get_pos() if not pos then return end self:set_gravity(-9.8) -- Return true when goal is reached if vec_dist(pos, goal) < box * 1.33 then _self:halt() return true end steer_timer = (steer_timer > 0 and steer_timer - _self.dtime) or 0.25 -- Get movement direction steer_to = (steer_timer > 0 and steer_to) or (steer_timer <= 0 and get_avoidance_dir(_self)) local goal_dir = steer_to or vec_dir(pos, goal) pos.y = pos.y + goal_dir.y local yaw = _self.object:get_yaw() local goal_yaw = dir2yaw(goal_dir) local speed = abs(_self.speed or 2) * speed_factor or 0.5 local turn_rate = abs(_self.turn_rate or 5) -- Movement local yaw_diff = abs(diff(yaw, goal_yaw)) if yaw_diff < pi * 0.25 or steer_to then _self:set_forward_velocity(speed) else _self:set_forward_velocity(speed * 0.33) end _self:turn_to(goal_yaw, turn_rate) end return func end)